US7671971B2ExpiredUtilityPatentIndex 62
Electro-optical method for measuring distance and detecting a non-ideal chirp profile
Est. expiryOct 9, 2024(expired)· nominal 20-yr term from priority
G01S 7/352G01S 13/343G01S 7/497G01S 17/34G01S 7/4915
62
PatentIndex Score
4
Cited by
11
References
30
Claims
Abstract
The invention relates to an electro-optical distance measuring method wherein frequency-modulated optical radiation is emitted onto at least one target to be measured. Once the radiation back-scattered to the target is received, the chirp of radiation is modeled by means of a phase function Φ(t) having parameters c j , thereby making description of the deviation of the chirp from the linear profile possible. The parameters used for description are at least partially determined from measurements or are coestimated during numerical signal processing.
Claims
exact text as granted — not AI-modified1. Electro-optical distance-measuring method comprising the following acts:
transmitting frequency-modulated optical electromagnetic radiation to at least one target to be surveyed, a chirp in a model signal as a frequency superposed on the radiation being described by
f
(
t
)
=
ⅆ
Φ
(
t
)
ⅆ
t
with a phase function
φ(t)=φ(t;c 1 , . . . , c m ) modeled with parameters C j ;
receiving radiation scattered back by the target;
converting the received radiation into at least one received signal; and
determining at least one distance to the at least one target from the received signal, wherein at least some of the parameters c j are determined directly from the received signal by solving a parameter estimation problem.
2. Distance-measuring method according to claim 1 , wherein the received radiation is converted with homodyne or heterodyne mixing.
3. Distance-measuring method according to claim 1 , wherein at least some of the parameters c j are determined by means of a maximum likelihood method, in particular together with the further system parameters and a transit time t k coordinated with at least one distance, so that the deviation of model signal from received signal has maximum probability density.
4. Distance-measuring method according to claim 1 , wherein the cardinality of the set of parameters c j is finite.
5. Distance-measuring method according to claim 1 , wherein the parameters c j are determined in each measurement.
6. Distance-measuring method according to claim 5 , wherein the parameters c j are determined in each measurement together with further system parameters and/or a transit time t k coordinated with at least one distance.
7. Distance-measuring method according to claim 1 , wherein a total phase change φ tot =φ(t b )−φ(t a ) in the transmitted signal during a known time interval is measured.
8. Distance-measuring method according to claim 7 , wherein a total phase change φ tot =φ(t b )−φ(t a ) in the transmitted signal during the measuring interval is measured.
9. Distance-measuring method according to claim 1 , wherein a total phase change φ tot =φ(t b )−φ(t a ) in the transmitted signal during a known time interval is measured by counting the passages of the transmitted signal through zero.
10. Distance-measuring method according to claim 1 , wherein the phase function according to
Φ
(
t
)
=
∑
j
=
1
m
c
j
Φ
j
(
t
)
is modeled as a finite linear combination of suitable base functions φ j (t).
11. Distance-measuring method according to claim 10 , wherein:
a general secondary condition Φ(t b ; c 1 , . . . , c m )−Φ(t a ; c 1 , . . . , c m )=Φ tot or a linear secondary condition
∑
j
=
1
m
[
Φ
j
(
t
b
)
-
Φ
j
(
t
a
)
]
·
c
j
=
Φ
tot
is taken into account for the coefficients c 1 . . . , c m in the signal evaluation.
12. Distance-measuring method according to claim 1 , wherein the phase function according to
Φ
(
t
)
=
∑
j
=
1
m
c
j
Φ
j
(
t
)
is modeled as a finite linear combination of suitable base functions φ j (t) with:
powers;
orthogonal polynomials;
wavelets; or
discrete delta functions at the sampling points as base functions.
13. Distance-measuring method according to claim 1 , wherein the phase function φ(t)=φ(t;c 1 , . . . , c m ) is modeled with nonlinear parameters c 1 , . . . , c m so that an optimization problem to be solved is also nonlinear with respect to the parameters c 1 , . . . , c m .
14. Distance-measuring method according to claim 1 , wherein approximate starting values for the transit times t k are calculated by means of frequency analysis and
f
k
(
t
)
=
{
2
e
(
t
0
-
t
k
)
,
homodyne
d
+
2
e
(
t
-
t
k
)
-
f
0
,
heterodyne
is calculated with approximate values of the parameters, where e(t) designates an echo signal and d designates a signal offset.
15. Distance-measuring method according to claim 14 , wherein the chirp slightly deviates from linearity.
16. Computer program product with program code, which is stored on a machine-readable medium or is embodied by an electromagnetic wave, for carrying out the method according to claim 1 .
17. Computer program product according to 16 , wherein the program code is configured to be executed by a computer.
18. Electro-optical distance-measuring apparatus, comprising;
a modulatable optical radiation source for production and for emission of optical radiation to a target to be surveyed;
a signal generator for modulation of the radiation source, a chirp as a frequency superposed on the radiation being described by
f
(
t
)
=
ⅆ
Φ
(
t
)
ⅆ
t
with a phase function φ(t);
a detector for receiving and for converting back-scattered radiation into received signals; and
a signal processor for processing the received signals, wherein the signal generator, detector, and signal processor are arranged and designed so that at least some of the parameters c j for modeling the phase function φ(t) are determined directly from the received signals by solving a parameter estimation problem.
19. Distance-measuring apparatus according to claim 18 , wherein the signal processor includes a digital signal processor.
20. Distance-measuring apparatus according to claim 18 , further comprising a mixer for carrying out a homodyne or heterodyne mixing procedure.
21. Distance-measuring apparatus according to claim 18 , wherein the signal generator, detector and signal processor are arranged and designed so that the parameters c j are determined in each measurement.
22. Distance-measuring apparatus according to claim 18 , wherein signal generator, detector and signal processor are arranged and designed so that the parameters c j are determined in each measurement together with further system parameters and/or a transit time t k coordinated with at least one distance.
23. Distance-measuring apparatus according to claim 18 , further comprising an apparatus for determining the total phase of the transmitted signal.
24. Distance-measuring apparatus according to claim 23 , wherein the apparatus for determining the total phase of the transmitted signal includes a counter.
25. Distance-measuring apparatus according to claim 18 , further comprising a sequence of optical or electrical superposition of the back-scattered radiation with a mixing signal and a nonlinearity for producing a mixed term.
26. Distance-measuring apparatus according to claim 25 , wherein the nonlinearity includes a quadratic nonlinearity.
27. Distance-measuring apparatus according to claim 18 , further comprising a sequence of optical or electrical superposition of the back-scattered radiation with a mixing signal and a nonlinearity for producing a mixed term with a down-circuit low-pass filter.
28. Distance-measuring apparatus according to claim 18 , further comprising a control which actuates the signal generator in such a way that deviations of the chirp from a linear frequency profile are compensated.
29. Distance-measuring apparatus according to claim 28 , wherein deviations of the chirp from a linear frequency profile are compensated in real time.
30. Distance-measuring apparatus according to claim 18 , wherein the distance-measuring apparatus is configured to perform the following:
transmit frequency-modulated optical electromagnetic radiation to at least one target to be surveyed, a chirp in a model signal as a frequency superposed on the radiation being described by
f
(
t
)
=
ⅆ
Φ
(
t
)
ⅆ
t
with a phase function
φ(t)=φ(t;c 1 , . . . , c m ) modeled with parameters C j ;
receive radiation scattered back by the target;
convert the received radiation into at least one received signal; and
determine at least one distance to the at least one target from the received signal, wherein at least some of the parameters c j are determined directly from the received signal by solving a parameter estimation problem.Cited by (0)
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